Intercolony distance predicts the decision to rescue or attack conspecifics in weaver ants

  • F. M. K. UyEmail author
  • J. D. Adcock
  • S. F. Jeffries
  • E. Pepere
Research Article


Group formation and recognition mechanisms can strongly influence the decision to cooperate or attack in animal societies. Therefore, testing how individuals recognize group membership, and the decision to cooperate or attack during social interactions is critical to understanding the evolution of sociality. We explore decision-making in the weaver ant Oecophylla smaragdina, a highly territorial and also cooperative species. Here, we report a previously undescribed rescue behavior for weaver ants, and determine the role of distance and group membership in residents’ decisions to either rescue or attack conspecifics in distress. First, we tested if residents preferentially rescued nestmates and attacked non-nestmates. Our results show that rescue was more likely for nestmates; however, surprisingly, conspecifics from neighboring colonies were rescued in 43% of the distress trials. Furthermore, attacks became more frequent as distance between colonies increased showing a dear enemy effect, which may be explained by familiarity, odor recognition, and/or relatedness. Our work exploring the factors that influence the decision to rescue or attack provides novel evidence to understand the underlying selective pressures that shape decisions of cooperation or conflict in highly cooperative societies.


Attack Conflict Cooperation Dear enemy Rescue Oecophylla smaragdina 



We thank the Ministry of Environment, Climate Change, Disaster Management and Metereology for permit RP/2014/002 to conduct fieldwork in the Solomon Islands, the Fagakoro community for access to their land, and the Manutage community for logistical assistance in Star Harbour. Johnson Pepere, George Wabeasi, James Suafuria and Lonsdale Taka provided assistance during fieldwork. Marc Seid, Al Uy, William Searcy, and members of the Uy and Searcy labs provided comments to improve earlier versions of the manuscript. This study was supported by the Biology Department and College of Arts and Sciences at the University of Miami to FMKU, and an Aresty Fund Scholarship awarded to SFJ.

Supplementary material

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Supplementary material 1 (XLSX 17 kb)


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Copyright information

© International Union for the Study of Social Insects (IUSSI) 2018

Authors and Affiliations

  1. 1.Department of Biology, Cox Science CenterUniversity of MiamiCoral GablesUSA
  2. 2.Nafinua Research StationFrigatebird IslandSolomon Islands

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